Liquid crystal display apparatus

ABSTRACT

In an LCD apparatus, a non-effective display region disposed between pixel electrodes and a light leakage region disposed on the pixel electrodes are covered by means of a light-leakage preventing layer and by overlapping color filters of a color filter substrate, thereby preventing the light from being leaked through the non-effective display region and the light leakage region. Accordingly, it is possible to prevent brightness of the light from being decreased and images displayed through the LCD apparatus from being deteriorated in quality.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a liquid crystal display (LCD) apparatus, and more particularly to an apparatus for preventing light from being leaked in an LCD apparatus to improve quality of images displayed thereon.

2. Description of the Related Art

To display images, in general, an LCD apparatus precisely controls liquid crystal using its optical anisotropic properties. The liquid crystal may be controlled by means of an electric field. For this reason, the liquid crystal is interposed between two electrodes.

The liquid crystal is arranged in a predetermined direction determined by an alignment groove, and tilted in a predetermined angle with respect to the alignment groove, thereby precisely controlling light transmittance of the liquid crystal.

FIG. 1 is a cross-sectional view showing an LCD panel of a conventional LCD apparatus.

Referring to FIG. 1, in order to display images having a high resolution through the LCD panel, the LCD panel requires a structure that is proper to precisely control small areas of the liquid crystal 10. For this purpose, a common electrode 20 to which a reference voltage is applied is disposed on the liquid crystal 10. Pixel electrodes 30, 35 that are divided in accordance with the resolution are formed under the liquid crystal 10, and the pixel electrodes 30 and 35 are opposite to the common electrode 20. The pixel electrodes 30 and 35 are formed not to be electrically short-circuited each other. A power supply module 40 is commonly connected with the pixel electrodes 30 and 35 to supply a desired power voltage to the pixel electrodes 30 and 35.

When dividing the pixel electrodes 30 and 35 into more than two in order to display images having the high resolution, there is a very small gap W between the pixel electrodes 30 and 35. It is not possible to control the liquid crystal 10 positioned at the gap W. That is, it is not possible to display images through the gap W disposed between the pixel electrodes 30 and 35, so that the quality of the image is lowered due to the light emitted through the gap W.

To prevent the quality of images from being lowered, the gap W positioned between the pixel electrodes 30 and 35 is screened by means of a light intercepting layer 50 having a band shape. The light intercepting layer 50 screens the power supply module 40, so that a user cannot recognize the power supply module 40.

However, if more than two pixel electrodes 30 and 35 are formed, light leaks through the gap W due to a horizontal electric field generated between the pixel electrodes 30 and 35. The horizontal electric field is formed between the edges of the pixel electrodes 30 and 35 in a concentric circle shape, and the horizontal electric field affects the vertical electric field by which the liquid crystal 10 is arranged ideally. Also, the liquid crystal 10 has a property to be arranged in parallel to directions of the horizontal and vertical electric fields.

When the liquid crystal 10 is disposed in parallel to the horizontal electric field, a reverse tilted region 70 is formed. As shown in FIG. 1, the liquid crystal 10 is reversely tilted at the pixel electrode 30, which is disposed to face a rubbing direction of the alignment groove 65 formed on the alignment layer 60. The liquid crystal 10 in the reverse tilted region 70 cannot be controlled, so that the light is leaked through the reverse tilted region 70. The reverse tilted region 70 is called as a declination line, which causes a low-quality image display.

BRIEF SUMMARY OF THE INVENTION

The present invention solves the aforementioned and other problems by providing a liquid crystal display apparatus in which light is prevented from leaking through declination lines disposed between pixel electrodes.

In one aspect of the invention, there is provided a liquid crystal display apparatus comprising: a TFT substrate having pixels in which first electrodes and power supply means for supplying a power voltage to the first electrodes are formed, and a first alignment layer on which at least one first alignment groove is formed in a first rubbing direction, a color filter substrate having color filters, second electrodes opposite to the first electrodes, and a second alignment layer on which a second alignment groove is formed in a second rubbing direction, liquid crystal interposed between the TFT substrate and the color filter substrate, the liquid crystal being tilted by the first and second alignment grooves and being twisted when the power voltage is applied to the first and second electrodes, and a light-leakage preventing means for screening a non-effective display region located between the pixels and a light leakage region having reverse tilted liquid crystal over a portion of the first electrodes and adjacent to the non-effective display region, the reverse tilted liquid crystal being formed in association with the first rubbing direction when the power voltage is applied to the first and second electrodes; and a backlight assembly for providing light to the liquid crystal display panel.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other objects and advantages of the present invention will become more apparently by describing in detail the exemplary embodiments thereof with reference to the accompanying drawings, in which:

FIG. 1 is a cross-sectional view showing an LCD panel of a conventional LCD apparatus;

FIG. 2 is a schematic view showing an LCD panel according to a preferred embodiment of the present invention;

FIG. 3 is a perspective view the LCD panel according to a preferred embodiment of the present invention;

FIG. 4 is a cross-sectional view cut along a line IV-IV showing a structure of the LCD panel shown in FIG. 3;

FIG. 5 is a circuit diagram showing a power supply module and a pixel electrode according to the present invention;

FIG. 6 is a schematic view showing a method of forming an alignment groove on an alignment layer disposed on a TFT substrate according to a preferred embodiment of the present invention;

FIG. 7 is a schematic view showing a structure of the TFT substrate according to a preferred embodiment of the present invention;

FIG. 8 is a coordinate system showing directions of first and second alignment grooves of TFT and color filter substrates according to the present invention;

FIGS. 9 to 15 are schematic views showing structures of the pixel electrodes and reverse tilted regions according to a preferred embodiment of the present invention;

FIGS. 16 and 17 are schematic views showing a light-leakage preventing layer and an overlap structure of color filters in the LCD panel driven by a line inversion driving method according to a preferred embodiment of the present invention;

FIGS. 18 and 19 are schematic views showing a light-leakage preventing layer and an overlap structure of color filters in the LCD panel driven by a column inversion driving method according to a preferred embodiment of the present invention; and

FIG. 20 is a schematic view showing a light-leakage preventing layer in the LCD panel driven by a dot inversion driving method according to a preferred embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Reference will now be made in detail to the exemplary embodiments of the present invention, examples of which are illustrated in the accompanying drawings. Hereinafter, exemplary embodiments are described with reference to the accompanying drawings.

FIG. 2 is a schematic view showing an LCD apparatus in accordance with an exemplary embodiment of the present invention.

Referring to FIG. 2, the LCD apparatus 300 includes an LCD panel assembly 100 and a backlight assembly 200. The backlight assembly 200 includes a light source 210 that generates linear light flux, a light guiding plate 220 that changes the linear light flux into planar light flux, and optical sheets 230 that increase uniformity of the brightness of the light emitted from the light guiding plate 220. The light emitted from the backlight assembly 200 is incident to the LCD panel assembly 100. The LCD panel assembly 100 has a minute-area control function of controlling transmittance of the light emitted from the backlight assembly 200 to display images.

FIG. 3 is a perspective view showing an exterior of the LCD panel assembly shown in FIG. 2, and FIG. 4 is a sectional view showing an interior of the LCD panel assembly shown in FIG. 3.

Referring to FIG. 3, the LCD panel assembly 100 includes a TFT substrate 110, the liquid crystal 130, a color filter substrate 120, a tape carrier package (TCP) 140, and a driving printed circuit board (driving PCB) 150.

As shown in FIG. 4, the TFT substrate 110 includes a glass substrate 111, pixel electrodes 112, a power supply module 113, a first alignment layer 114 and a first alignment groove 114 a. The reference numeral 115 indicates a polarizing plate 115.

Referring to FIGS. 4 and 5, the power supply module 113 is disposed on the glass substrate 111. The power supply module 113 includes TFTs 113 a and common signal lines 113 g and 113 h. The TFTs 113 a are disposed on the glass substrate 111 in a matrix form, and the number of TFTs 113 a is decided in accordance with a resolution of the LCD panel assembly 100. For example, when the resolution is 800×600, the LCD panel assembly 100 requires 800×600×3 TFTs to display images in a full color mode.

Each of the TFTs 113 a disposed on the glass substrate 113 a includes two signal input terminals and one signal output terminal. The common signal lines 113 g and 113 h are used to drive the TFTs 113 a.

Hereinafter, the connection between the TFTs 113 a and common signal lines 113 g and 113 h will be described with reference to FIGS. 4 to 7.

On the glass substrate 111, a plurality of gate electrodes 113 b operating as input terminals of the TFTs 113 a are formed in a matrix form. The gate electrodes 113 b are connected with one of the common signal lines operating as gate lines 113 g. The gate lines 113 g are formed together with the gate electrodes 113 b.

An insulating layer 113 c is formed on each of the gate electrodes 113 b, and a channel layer 113 d is partially formed on the insulating layer 113 c corresponding to the gate electrode 113 b. The channel layer 113 d includes semiconductor material, such as amorphous silicon, polycrystalline silicon or single crystal silicon. The channel layer 113 d is nonconductive when a power voltage is not applied to the gate electrode 113 b, and becomes conductive when a power voltage is applied to the gate electrode 113 b.

On the channel layer 113 d, n⁺ amorphous silicon thin film where n+ ion is implanted into the amorphous silicon may be formed. The implanted amorphous silicon layer is divided into first and second portions so as not to be electrically short-circuited each other, and is called as an ohmic contact layer.

Source electrodes 113 e corresponding to one of the two input terminals of the TFTs 113 a are formed on the first portion of the two ohmic contact layers, and the source electrodes 113 e are connected with a data line 113 h arranged in the column direction, which is one of the common signal lines 113 g and 113 h. Drain electrodes 113 f operating as signal output terminals of the TFTs 113 a are formed on the second portion of the two ohmic contact layers.

As mentioned above, the power supply module 113 has a circuit configuration that is proper to supply a power voltage to each of the drain electrodes 113 f of the TFTs 113 a. The power supply module 113 may supply a power voltage having a different voltage level to each area of the glass substrate divided by the number of the TFTs 113 a.

Pixel electrodes 112 are formed on the corresponding drain electrodes 113 f, and the pixel electrodes 112 are formed not to be electrically short-circuited each other. Referring to FIG. 4, there exists an empty space W1 between a first pixel electrode 112 a and a second pixel electrode 112 b. Hereinafter, the empty space W1 between the first and second pixel electrodes 112 a and 112 b is defined as a non-effective display region W1.

On the other hand, a first alignment layer 114 comprised of polyamide material is formed over the glass substrate 111 on which the pixel electrodes 112 are formed. A rubbing roller 300 on which a rubbing cloth 310 is wound makes a first alignment groove 114 a on the first alignment layer 114 in a predetermined direction as shown in FIG. 6.

The color filter substrate 120 is disposed on the TFT substrate 110. The color filter substrate 120 includes a glass substrate 121, a light-leakage preventing layer 122, color filters 123 (123 a, 123 b), a common electrode 124, a second alignment layer 125 and a second alignment groove 125 a. The reference numeral 126 indicates a polarizing plate. The color filters 123 includes a red color filter 123 a that emits light having a wavelength of red light, a green color filter 123 b that emits light having a wavelength of green light and a blue color filter (not shown) that emits light having a wavelength of blue light. The red and green color filters 123 a and 123 b are formed in positions corresponding to the first and second pixel electrodes 112 a and 112 b, respectively, and the light-leakage preventing layer 122 is formed between the red, green and blue color filters 123. A transparent common electrode 124 is disposed over the glass substrate 121 of the color filter substrate 120, and then the second alignment layer 125 having the second alignment groove 125 a is disposed on the common electrode 124.

The second alignment groove 125 a is formed in a different direction in comparison with the first alignment groove 114 a. The liquid crystal 130 is injected between the TFT substrate 110 and the color filter substrate 120, and is sealed therebetween with a sealant.

The non-effective display region W1 is formed between the first and second pixel electrodes 112 a and 112 b, and the non-effective display region may be formed on a portion of the second pixel electrode 112 b due to a horizontal electric field. The horizontal electric field is formed on the second pixel electrode 112 b in a direction that is related to the direction in which the first alignment groove 114 a is disposed. The region in which the horizontal electric field is disposed instead of a vertical electric field is defined as a reverse tilted region W2. As mentioned above, the position of the reverse tilted region W2 is decided by means of the first alignment groove 114 a of the first alignment layer 114.

In order to define the direction of the first alignment groove 114 a, the gate line 113 g is set up as an X-axis, and the data line 113 h orthogonal to the gate line 113 g is set up as a Y-axis. The point that the gate line 113 g meets with the data line 113 h is defined as an origin “o”. As shown in FIG. 8, a first region has plus X and Y values, a second region has plus X value and minus Y value, a third region has minus X and Y values, and a fourth region has minus X value and plus Y value.

As shown in FIGS. 8 and 9, the first alignment groove 114 a formed on the pixels 112 of the TFT substrate 110 is rubbed in a direction from the third region toward the first region, and the second alignment groove 125 a formed on the color filter substrate 120 is rubbed in a direction from the second region toward the fourth region. Thus, as shown in FIG. 9, the reverse tilted region W2 of the liquid crystal 130 is formed on edge portions 112 c and 112 d of the pixel electrodes 112, the edge portions 112 c and 112 d are adjacent to each other and is opposite to the rubbing direction of the first alignment groove 114 a. The reverse tilted region W2 of the liquid crystal 130 is formed on every pixel electrode 112.

As shown in FIG. 9, the reverse tilted region formed on the edge portion 112 d parallel to the gate line 113 g is defined as a first reverse tilted region W3, and the reverse tilted region formed on the edge portion 112 c parallel to the data line 113 h is defined as a second reverse tilted region W4. Namely, The reverse tilted region W2 is comprised of the first and second reverse tilted regions W3 and W4.

As another exemplary embodiment, referring to the FIG. 10, the first alignment groove 114 a formed on the pixels 112 of the TFT substrate 110 is rubbed in a direction from the second region toward the fourth region, and the second alignment groove 125 a formed on the color filter substrate 120 is rubbed in a direction from the third region toward the first region. Thus, the reverse tilted region W2 of the liquid crystal 130 is formed on edge portions 112 d and 112 f of the pixel electrodes 112, the edge portions 112 d and 112 f are adjacent to each other and are opposite to the rubbing direction of the first alignment groove 114 a. The reverse tilted region W2 of the liquid crystal 130 is formed on every pixel electrode 112.

Referring to FIG. 11, the reverse tilted region formed on the edge portion 112 d parallel to the gate line 113 g is defined as the first reverse tilted region W3, and the reverse tilted region formed on the edge portion 112 f parallel to the data line 113 h is defined as a second reverse tilted region W4.

As another exemplary embodiment, referring to FIG. 12, the first alignment groove 114 a formed on the pixels 112 of the TFT substrate 110 is rubbed in a direction from the fourth region toward the second region, and the second alignment groove 125 a formed on the color filter substrate 120 is rubbed in a direction from the third region toward the first region. Thus, the reverse tilted region W2 of the liquid crystal 130 is formed on edge portions 112 c and 112 e of the pixel electrodes 112, the edge portions 112 c and 112 e are adjacent to each other and are opposite to the rubbing direction of the first alignment groove 114 a. The reverse tilted region W2 of the liquid crystal 130 is formed on every pixel electrode 112.

Referring to FIG. 13, the reverse tilted region formed on the edge portion 112 e parallel to the gate line 113 g is defined as the first reverse tilted region W3, and the reverse tilted region formed on the edge portion 112 c parallel to the data line 113 h is defined as the second reverse tilted region W4.

As another exemplary embodiment, referring to FIG. 14, the first alignment groove 114 a formed on the pixels 112 of the TFT substrate 110 is rubbed in a direction from the first region toward the third region, and the second alignment groove 125 a formed on the color filter substrate 120 is rubbed in a direction from the fourth region toward the second region. Thus, the reverse tilted region W2 of the liquid crystal 130 is formed on edge portions 112 e and 112 f of the pixel electrodes 112, the edge portions 112 e and 112 f are adjacent to each other and are opposite to the rubbing direction of the first alignment groove 114 a. The reverse tilted region W2 of the liquid crystal 130 is formed on every pixel electrode 112.

As shown in FIG. 15, the reverse tilted region formed on the edge portion 112 e parallel to the gate line 113 g is defined as the first reverse tilted region W3, and the reverse tilted region formed on the edge portion 112 f parallel to the data line 113 h is defined as the second reverse tilted region W4.

Referring to FIGS. 9 to 15, the first reverse tilted region W3 is formed only on one of the first and second pixel electrodes 112 a and 112 b adjacent to each other, i.e., on the second pixel electrode 112 b. Similarly, the second reverse tilted region W4 is formed only on one of the first and second pixel electrodes 112 a and 112 b adjacent to each other, i.e., on the second pixel electrode 112 b.

The liquid crystal 130 is not controlled in the first and second reverse tilted regions W3 and W4, so that the light leakage occurs within the first and second reverse tilted regions W3 and W4. Thus, the first and second reverse tilted regions W3 and W4 as well as the non-effective display region W1 have to be screened to prevent the light from being leaked. As shown in FIG. 4, the light-leakage preventing layer 122 covers the first and second reverse tilted regions W3 and W4 and the non-effective display region W1. The light-leakage preventing layer 122 may be comprised of chromium (Cr) material.

One edge of the light-leakage preventing layer 122 is positioned at a boundary between the pixel electrode 112 a, on which the first and second reverse tilted regions W3 and W4 are not formed, and the non-effective display region W1. The light-leakage preventing layer 122 is extended to the boundary of the pixel electrode 112 b, on which the first and second reverse tilted regions W3 and W4 are formed, and the first and second reverse tilted regions W3 and W4. Namely, the other edge of the light-leakage preventing layer 122 is positioned at the boundary of the pixel electrode 112 b and the reverse tilted regions W3 and W4

The intensity of the light leaked through the first reverse tilted region W3 is different from that of the light leaked through the second reverse tilted region W4. The intensity varies according to a driving method of the LCD apparatus.

As shown in FIG. 16, in the pixel electrodes formed in N×N matrix, a line inversion driving method is used in which an electric field having a plus (+) polarity is applied to the pixel electrodes arranged in the (n−1)th column and an electric field having a minus (−) polarity is applied to the pixel electrodes arranged in the (n)th column.

When the electric field is applied to the pixel electrodes by the line inversion driving method, the difference of electric field between the adjacent pixel electrodes arranged in different rows is larger than the difference of electric field between the adjacent pixel electrodes arranged in a same row.

For example, as shown in FIG. 16, when the power voltages applied to the pixel electrodes arranged in the (n−1)th row are +5, +4 and +3 volts, and the power voltages applied to the pixel electrodes arranged in the (n)th row are −10, −9 and −10 volts, the difference of electric field between the pixel electrodes arranged in the (n−1)th row or the difference of electric field between the pixel electrodes arranged in the (n)th row is about Δ1 volt. However, the difference of electric field between the (n−2)th, (n−1)th, (n)th column pixel electrodes arranged in the (n−1)th row and the (n−2)th, (n−1)th, (n)th column pixel electrodes arranged in the (n)th row, respectively, is over Δ10 volts. Thus, images displayed through the first reverse tilted region W3 have a worse quality than that of images displayed through the second reverse tilted region W4.

When the line inversion driving method is used, the first reverse tilted region W3 and the non-effective display region W1 have to be covered by means of the light-leakage preventing layer 122. Specifically, the light-leakage preventing layer 122 is formed in a direction parallel to the gate line 113 g. The reference symbol C indicates a center line between two pixel electrodes adjacent to each other.

Although the first reverse tilted region W3 and the non-effective display region W1 is screened by the light-leakage preventing layer 122, the light leaked from the second reverse tilted region W4 may still exist. Accordingly, the second reverse tilted region W4 may preferably be screened. The color filters are overlapped in FIG. 17 to screen the second reverse tilted region W4. The red color filter 123 a, the green color filter 123 b and the blue color filter 123 c have a band shape in order to cover the pixel electrodes arranged in (n−2)th, (n−1)th and (n)th columns, respectively.

Referring to FIG. 17, the overlap between the color filters screens the non-effective display region W1 and the second reverse tilted region W4. The red color filter 123 a covers the pixel electrodes having +5 volts and −10 volts, and extends to the second reverse tilted region W4 of the pixel electrodes having +4 volts and −9 volts. The green color filter 123 b covers the pixel electrodes having + 4 volts and −9 volts, and extends to the edges of the pixel electrodes having + 5 volts and −10 volts and the second reverse tilted region W4 of the pixel electrodes having + 3 volts and −10 volts. The blue color filter 123 c covers the pixel electrodes having + 3 volts and −10 volts, and extends to the edges of the pixel electrodes having + 4 volts and −9 volts.

As a result, the red, green and blue color filters 123 a, 123 b and 123 c are overlapped with each other in the hatched areas of FIG. 17. The light transmittance decreases at the areas in which the red and green color filters are overlapped and the green and blue color filters are overlapped, so that the overlapped areas screen the non-effective display region W1 and the second reverse tilted region W4.

FIGS. 18 and 19 are diagrams showing an LCD panel driven by a column inversion driving method.

As shown in FIG. 18, in the pixel electrodes formed in N×N matrix, the column inversion driving method is used in which the electric field having the plus (+) polarity is applied to the pixel electrodes arranged in the (n−2)th column, the electric field having the minus (−) polarity is applied to the pixel electrodes arranged in the (n−1)th column and the electric field having the plus (+) polarity is applied to the pixel electrodes arranged in the (n)th column.

When the electric fields are formed on the respective pixel electrodes by the column inversion driving method, the difference of electric field between the adjacent pixel electrodes arranged in a same column is smaller than the difference of electric field between the adjacent pixel electrodes arranged in different columns.

For example, when the power voltages applied to the (n−1)th and (n)th row pixel electrodes arranged in the (n−2)th column are +1 and +6 volts, respectively, the power voltages applied to the (n−1)th and (n)th row pixel electrodes arranged in the (n−1)th column are −5 and −2 volts, respectively, and the power voltages applied to the (n−1)th and (n)th row pixel electrodes arranged in the (n)th row are +7 and +4 volts, respectively, the difference of electric field between the (n−1)th and (n)th row pixel electrodes arranged in the (n−2)th, (n−1)th or (n)th column is smaller than the electric field difference between the adjacent column pixel electrodes arranged in different columns such as the (n−2) th, (n−1) th and (n) th column. Thus, images displayed through the second reverse tilted region W4 have a lower quality than images displayed through the first reverse tilted region W3.

When the column inversion driving method is used, the second reverse tilted region W4 and the non-effective display region W1 are covered by means of the light-leakage preventing layer 122. Specifically, the light-leakage preventing layer 122 is formed in a direction parallel to the data line 113 h. The light-leakage preventing layer 122 is formed to cover a minimum portion of the pixel electrodes, on which the second reverse tilted region W4 is not formed, adjacent to the pixel electrodes, on which the second reverse tilted region W4 is formed.

Although the second reverse tilted region W4 and the non-effective display region W1 is screened by the light-leakage preventing layer 122, the light leaked from the first reverse tilted region W3 may still exist. Accordingly, the first reverse tilted region W3 may preferably be screened. The color filters are overlapped, as shown in FIG. 19, to screen the first reverse tilted region W3.

The red color filter 129 a, the green color filter 129 b and the blue color filter (not shown) have a band shape that covers the pixel electrodes arranged in the (n−1)th and (n)th rows.

Referring to FIG. 19, the overlap of the color filters screens the non-effective display region W1 and the first reverse tilted region W3. Specifically, the red color filter 129 a covers the whole pixel electrodes having +1, −5 and +7 volts, and extends to the edges of the pixel electrodes having +6, −2 and +4 volts.

The green color filter 129 b covers the whole pixel electrodes having +6, −2 and +4 volts, and extends to the first reverse tilted region W3 of the pixel electrodes having +1, −5 and +7 volts.

Accordingly, as shown in FIG. 19, the red and green color filters 129 a and 129 b are overlapped with each other in the hatched area. The light transmittance decreases at the areas in which the red and green color filters 129 a and 129 b are overlapped, so that the overlapped area screens the non-effective display region W1 and the first reverse tilted region W3.

FIG. 20 is a view showing an LCD panel driven by a dot inversion driving method.

By employing the dot inversion driving method, the polarities of the pixel electrodes are inverted between adjacent pixel electrodes arranged in different columns and different rows. When driving the LCD panel with the dot inversion driving method, the amount of the light leaked through the first and second reverse tilted regions W3 and W4 increases more than it does in case of employing the line or column inversion driving method, so that it may be difficult for the method of overlapping the color filters to efficiently prevent the quality of images from being lowered.

In this case, the first and second reverse tilted regions W3 and W4 and the non-effective display region W1 are covered by means of the light-leakage preventing layer 122, thereby increasing the quality of images displayed.

According to the aforementioned LCD, the reverse tilted regions of the liquid crystal that causes light leakage are covered by means of the light-leakage preventing layer and/or by overlapping the color filters each other. Thus, it is possible to prevent the light from being leaked through the reverse tilted regions without increasing the size of the light-leakage preventing layer and decreasing an opening ratio of the pixels by optimizing the position of the light-leakage preventing layer.

This invention has been described above with reference to the aforementioned embodiments. It is evident, however, that many alternative modifications and variations will be apparent to those having skills in the art in light of the foregoing description. Accordingly, the present invention embraces all such alternative modifications and variations as fall within the spirit and scope of the appended claims. 

1-16. (canceled)
 17. A liquid crystal display (LCD) apparatus comprising: a liquid crystal display panel including: a thin film transistor (TFT) substrate having a first base substrate, and a plurality of pixel electrodes and a power supply module formed on the first base substrate, the power supply module including a first signal line extending a first direction and a second signal line extending a second direction substantially perpendicular to the first direction, each of the pixel electrode having first and second edges substantially parallel with the first direction, and third and fourth edges substantially parallel with the second direction, a reverse tilted region having a light leakage region through which a light leaks being formed in at least one of the first, second, third and fourth edges of the pixel electrode; a color filter substrate having a plurality of color filters, a common electrode formed on the color filters, the color filters respectively corresponding to the pixel electrodes; a liquid crystal disposed between the TFT substrate and the color filter substrate; and a light-leakage preventing layer disposed over the pixel electrodes and blocking a non-effective display region and the light leakage region, the non-effective display region being defined as an area between the pixel electrodes adjacent to each other; and a backlight assembly providing the light to the liquid crystal display panel.
 18. The LCD apparatus of claim 17, wherein the non-effective display region and the reverse tilted region partially overlap with each other.
 19. The LCD apparatus of claim 18, wherein the TFT substrate further comprises: a first alignment layer formed on the pixel electrodes and the power supply module; and a first alignment groove formed on the first alignment layer and aligned in a first rubbing direction.
 20. The LCD apparatus of claim 19, wherein the color filter substrate further comprises: a second alignment layer formed on the common electrode; and a second alignment groove formed on the second alignment layer and aligned in a second rubbing direction.
 21. The LCD apparatus of claim 20, wherein the reverse tilted region is caused by the first alignment layer in the first rubbing direction when an electric field is applied to the pixel electrodes.
 22. The LCD apparatus of claim 18, wherein the light-leakage preventing layer is formed along the first direction when the reverse tilted region is formed adjacent to at least one of the first and second edges of the pixel electrode.
 23. The LCD apparatus of claim 22, wherein a center line of the light-leakage preventing layer is shifted to the first edge of the pixel electrode when the reverse tilted region is formed adjacent to the first edge of the pixel electrode, and the center line of the light-leakage preventing layer is shifted to the second edge of the pixel electrode when the reverse tilted region is formed adjacent to the second edge of the pixel electrode, so that the non-effective display region and the light leakage region are entirely blocked.
 24. The LCD apparatus of claim 22, wherein the color filters adjacent to each other extend along the first direction and overlap with each other, to block the non-effective display region and the light leakage region, when the reverse tilted region is formed adjacent to at least one of the third and fourth edges of the pixel electrode.
 25. The LCD apparatus of claim 24, wherein each of the color filters includes one of red, green and blue color filters.
 26. The LCD apparatus of claim 22, wherein the light-leakage preventing layer is formed along the second direction when the reverse tilted region is formed adjacent to at least one of the third and fourth edges of the pixel electrode.
 27. The LCD apparatus of claim 26, wherein the center line of the light-leakage preventing layer is shifted to the third edge of the pixel electrode when the reverse tilted region is formed adjacent to the third edge of the pixel electrode, and the center line of the light-leakage preventing layer is shifted to the fourth edge of the pixel electrode when the reverse tilted region is formed adjacent to the fourth edge of the pixel electrode, so that the non-effective display region and the light leakage region are entirely blocked.
 28. The LCD apparatus of claim 18, wherein the light-leakage preventing layer is formed along the second direction when the reverse tilted region is formed adjacent to at least one of the third and fourth edges of the pixel electrode.
 29. The LCD apparatus of claim 28, wherein the center line of the light-leakage preventing layer is shifted to the third edge of the pixel electrode when the reverse tilted region is formed adjacent to the third edge of the pixel electrode, and the center line of the light-leakage preventing layer is shifted to the fourth edge of the pixel electrode when the reverse tilted region is formed adjacent to the fourth edge of the pixel electrode, so that the non-effective display region and the light leakage region are entirely blocked.
 30. The LCD apparatus of claim 28, wherein the color filters adjacent to each other extend along the second direction and overlap with each other to block the non-effective display region and the light leakage region, when the reverse tilted region is formed adjacent to at least one of the first and second edges of the pixel electrode.
 31. The LCD apparatus of claim 30, wherein each of the color filters includes one of red, green and blue color filters. 